Your search keyword '"Loh, Aaron"' showing total 7 results

1. Acquiring Functional Magnetic Resonance Imaging in Patients Treated with Deep Brain Stimulation

Author

Gwun, Dave, Loh, Aaron, Vetkas, Artur, Boutet, Alexandre, Hodaie, Mojgan, Kalia, Suneil K., Fasano, Alfonso, Lozano, Andres M., Boutet, Alexandre, editor, and Lozano, Andres M., editor

Published

2022

2. A Functional Connectome of Parkinson's Disease Patients Prior to Deep Brain Stimulation: A Tool for Disease-Specific Connectivity Analyses.

Author

Loh, Aaron, Boutet, Alexandre, Germann, Jürgen, Al-Fatly, Bassam, Elias, Gavin J. B., Neudorfer, Clemens, Krotz, Jillian, Wong, Emily H. Y., Parmar, Roohie, Gramer, Robert, Paff, Michelle, Horn, Andreas, Chen, J. Jean, Azevedo, Paula, Fasano, Alfonso, Munhoz, Renato P., Hodaie, Mojgan, Kalia, Suneil K., Kucharczyk, Walter, and Lozano, Andres M.

Subjects

DEEP brain stimulation, PARKINSON'S disease, MOVEMENT disorders, LARGE-scale brain networks, FUNCTIONAL magnetic resonance imaging

Abstract

Finally, we showed that despite the considerable disparities in size of the Tor-PD ( I n i = 75) and Healthy connectomes ( I n i = 1,000), when performing analyses with PD DBS patient data, functional connectivity of VTAs to certain motor ROIs computed with the Tor-PD connectome could significantly explain variance in clinical outcome, whereas connectivity computed with the Healthy connectome could not. Moreover, when we examined the effect of different MRI hardware, the number of significantly different voxels between raw I r- i maps from either connectome was the same when computed with the full Tor-PD connectome or a subset of the Tor-PD connectome using 3T rs-fMRI acquisitions (58 scans) only. Keywords: Parkinson's disease; functional connectivity; connectomics; neuromodulation; functional magnetic resonance imaging EN Parkinson's disease functional connectivity connectomics neuromodulation functional magnetic resonance imaging 1 9 9 06/28/22 20220624 NES 220624 Background and Summary A wide range of disorders are thought to arise from dysfunction in brain circuitry (Bonelli and Cummings, [4]). [Extracted from the article]

Published

2022

3. 3T MRI of rapid brain activity changes driven by subcallosal cingulate deep brain stimulation.

Author

Elias, Gavin J B, Germann, Jürgen, Boutet, Alexandre, Loh, Aaron, Li, Bryan, Pancholi, Aditya, Beyn, Michelle E, Naheed, Asma, Bennett, Nicole, Pinto, Jessica, Bhat, Venkat, Giacobbe, Peter, Woodside, D Blake, Kennedy, Sidney H, and Lozano, Andres M

Subjects

DEEP brain stimulation, BRAIN, LIMBIC system, MAGNETIC resonance imaging, RESEARCH funding

Abstract

Deep brain stimulation targeting the subcallosal cingulate area, a hub with multiple axonal projections, has shown therapeutic potential for treatment-resistant mood disorders. While subcallosal cingulate deep brain stimulation drives long-term metabolic changes in corticolimbic circuits, the brain areas that are directly modulated by electrical stimulation of this region are not known. We used 3.0 T functional MRI to map the topography of acute brain changes produced by stimulation in an initial cohort of 12 patients with fully implanted deep brain stimulation devices targeting the subcallosal cingulate area. Four additional subcallosal cingulate deep brain stimulation patients were also scanned and employed as a validation cohort. Participants underwent resting state scans (n = 78 acquisitions overall) during (i) inactive deep brain stimulation; (ii) clinically optimal active deep brain stimulation; and (iii) suboptimal active deep brain stimulation. All scans were acquired within a single MRI session, each separated by a 5-min washout period. Analysis of the amplitude of low-frequency fluctuations in each sequence indicated that clinically optimal deep brain stimulation reduced spontaneous brain activity in several areas, including the bilateral dorsal anterior cingulate cortex, the bilateral posterior cingulate cortex, the bilateral precuneus and the left inferior parietal lobule (PBonferroni < 0.0001). Stimulation-induced dorsal anterior cingulate cortex signal reduction correlated with immediate within-session mood fluctuations, was greater at optimal versus suboptimal settings and was related to local cingulum bundle engagement. Moreover, linear modelling showed that immediate changes in dorsal anterior cingulate cortex, posterior cingulate cortex and precuneus activity could predict individual long-term antidepressant improvement. A model derived from the primary cohort that incorporated amplitude of low-frequency fluctuations changes in these three areas (along with preoperative symptom severity) explained 55% of the variance in clinical improvement in that cohort. The same model also explained 93% of the variance in the out-of-sample validation cohort. Additionally, all three brain areas exhibited significant changes in functional connectivity between active and inactive deep brain stimulation states (PBonferroni < 0.01). These results provide insight into the network-level mechanisms of subcallosal cingulate deep brain stimulation and point towards potential acute biomarkers of clinical response that could help to optimize and personalize this therapy. [ABSTRACT FROM AUTHOR]

Published

2022

4. Habenular Involvement in Response to Subcallosal Cingulate Deep Brain Stimulation for Depression.

Author

Elias, Gavin J. B., Germann, Jürgen, Loh, Aaron, Boutet, Alexandre, Pancholi, Aditya, Beyn, Michelle E., Bhat, Venkat, Woodside, D. Blake, Giacobbe, Peter, Kennedy, Sidney H., and Lozano, Andres M.

Subjects

DEEP brain stimulation, BRAIN stimulation, CINGULATE cortex, MOOD (Psychology), FUNCTIONAL magnetic resonance imaging, MENTAL depression

Abstract

The habenula (Hb) is a small, evolutionarily conserved epithalamic structure implicated in functions such as reward and mood regulation. Prior imaging work suggests that Hb's structural and functional properties may relate to treatment response in depression and other mood disorders. We used multimodal MRI techniques to investigate the potential involvement of Hb in response to subcallosal cingulate area deep brain stimulation (SCC-DBS) for treatment-resistant mood disorders. Using an automated segmentation technique, we compared Hb volume at baseline and at a subsequent post-operative timepoint (4.4 ± 3.0 years after surgery) in a cohort of 32 patients who received SCC-DBS. Clinical response to treatment (≥50% decrease in HAMD-17 from baseline to 12 months post-operation) was significantly associated with longitudinal Hb volume change: responders tended to have increased Hb volume over time, while non-responders showed decreased Hb volume (t = 2.4, p = 0.021). We additionally used functional MRI (fMRI) in a subcohort of SCC-DBS patients (n = 12) to investigate immediate within-patient changes in Hb functional connectivity associated with SCC-DBS stimulation. Active DBS was significantly associated with increased Hb connectivity to several prefrontal and corticolimbic regions (TFCE-adjusted p Bonferroni < 0.0001), many of which have been previously implicated in the neurocircuitry of depression. Taken together, our results suggest that Hb may play an important role in the antidepressant effect of SCC-DBS. [ABSTRACT FROM AUTHOR]

Published

2022

5. Potential optimization of focused ultrasound capsulotomy for obsessive compulsive disorder.

Author

Germann, Jürgen, Elias, Gavin J B, Neudorfer, Clemens, Boutet, Alexandre, Chow, Clement T, Wong, Emily H Y, Parmar, Roohie, Gouveia, Flavia Venetucci, Loh, Aaron, Giacobbe, Peter, Kim, Se Joo, Jung, Hyun Ho, Bhat, Venkat, Kucharczyk, Walter, Chang, Jin Woo, and Lozano, Andres M

Subjects

BRAIN stimulation, OBSESSIVE-compulsive disorder, DEEP brain stimulation, DIFFUSION tensor imaging, FUNCTIONAL magnetic resonance imaging, DIFFUSION magnetic resonance imaging, RESEARCH, NEURAL pathways, COMPUTER-assisted surgery, NEUROSURGERY, OPERATIVE surgery, RESEARCH methodology, RETROSPECTIVE studies, EVALUATION research, TREATMENT effectiveness, COMPARATIVE studies, RESEARCH funding, LONGITUDINAL method

Abstract

Obsessive-compulsive disorder is a debilitating and often refractory psychiatric disorder. Magnetic resonance-guided focused ultrasound is a novel, minimally invasive neuromodulatory technique that has shown promise in treating this condition. We investigated the relationship between lesion location and long-term outcome in patients with obsessive-compulsive disorder treated with focused ultrasound to discern the optimal lesion location and elucidate the efficacious network underlying symptom alleviation. Postoperative images of 11 patients who underwent focused ultrasound capsulotomy were used to correlate lesion characteristics with symptom improvement at 1-year follow-up. Normative resting-state functional MRI and normative diffusion MRI-based tractography analyses were used to determine the networks associated with successful lesions. Patients with obsessive-compulsive disorder treated with inferior thalamic peduncle deep brain stimulation (n = 5) and lesions from the literature implicated in obsessive-compulsive disorder (n = 18) were used for external validation. Successful long-term relief of obsessive-compulsive disorder was associated with lesions that included a specific area in the dorsal anterior limb of the internal capsule. Normative resting-state functional MRI analysis showed that lesion engagement of areas 24 and 46 was significantly associated with clinical outcomes (R = 0.79, P = 0.004). The key role of areas 24 and 46 was confirmed by (i) normative diffusion MRI-based tractography analysis, showing that streamlines associated with better outcome projected to these areas; (ii) association of these areas with outcomes in patients receiving inferior thalamic peduncle deep brain stimulation (R = 0.83, P = 0.003); and (iii) the connectedness of these areas to obsessive-compulsive disorder-causing lesions, as identified using literature-based lesion network mapping. These results provide considerations for target improvement, outlining the specific area of the internal capsule critical for successful magnetic resonance-guided focused ultrasound outcome and demonstrating that discrete frontal areas are involved in symptom relief. This could help refine focused ultrasound treatment for obsessive-compulsive disorder and provide a network-based rationale for potential alternative targets. [ABSTRACT FROM AUTHOR]

Published

2021

6. Predicting optimal deep brain stimulation parameters for Parkinson's disease using functional MRI and machine learning.

Author

Boutet, Alexandre, Madhavan, Radhika, Elias, Gavin J. B., Joel, Suresh E., Gramer, Robert, Ranjan, Manish, Paramanandam, Vijayashankar, Xu, David, Germann, Jurgen, Loh, Aaron, Kalia, Suneil K., Hodaie, Mojgan, Li, Bryan, Prasad, Sreeram, Coblentz, Ailish, Munhoz, Renato P., Ashe, Jeffrey, Kucharczyk, Walter, Fasano, Alfonso, and Lozano, Andres M.

Subjects

DEEP brain stimulation, BRAIN stimulation, PARKINSON'S disease, FUNCTIONAL magnetic resonance imaging, MACHINE learning

Abstract

Commonly used for Parkinson's disease (PD), deep brain stimulation (DBS) produces marked clinical benefits when optimized. However, assessing the large number of possible stimulation settings (i.e., programming) requires numerous clinic visits. Here, we examine whether functional magnetic resonance imaging (fMRI) can be used to predict optimal stimulation settings for individual patients. We analyze 3 T fMRI data prospectively acquired as part of an observational trial in 67 PD patients using optimal and non-optimal stimulation settings. Clinically optimal stimulation produces a characteristic fMRI brain response pattern marked by preferential engagement of the motor circuit. Then, we build a machine learning model predicting optimal vs. non-optimal settings using the fMRI patterns of 39 PD patients with a priori clinically optimized DBS (88% accuracy). The model predicts optimal stimulation settings in unseen datasets: a priori clinically optimized and stimulation-naïve PD patients. We propose that fMRI brain responses to DBS stimulation in PD patients could represent an objective biomarker of clinical response. Upon further validation with additional studies, these findings may open the door to functional imaging-assisted DBS programming. Deep brain stimulation programming for Parkinson's disease entails the assessment of a large number of possible simulation settings, requiring numerous clinic visits after surgery. Here, the authors show that patterns of functional MRI can predict the optimal stimulation settings. [ABSTRACT FROM AUTHOR]

Published

2021

7. Blood oxygen level-dependent (BOLD) response patterns with thalamic deep brain stimulation in patients with medically refractory epilepsy.

Author

Sarica, Can, Yamamoto, Kazuaki, Loh, Aaron, Elias, Gavin J.B., Boutet, Alexandre, Madhavan, Radhika, Germann, Jürgen, Zemmar, Ajmal, Gwun, Dave, Tasserie, Jordy, Andrade, Danielle M., Hodaie, Mojgan, Kalia, Suneil K., Wennberg, Richard A., and Lozano, Andres M.

Subjects

*BRAIN stimulation, *DEEP brain stimulation, *NEURAL stimulation, *VAGUS nerve, *OXYGEN in the blood, *FUNCTIONAL magnetic resonance imaging, *CINGULATE cortex, *EPILEPSY

Abstract

• ANT-DBS is an emerging treatment for patients with medically refractory epilepsy. • Exact mechanism of action and optimal stimulation parameters of ANT-DBS are uncertain. • Anterior thalamic DBS increased signal in putamen, thalamus, precuneus and cingulate. • Moving the stimulation site within thalamus produced different BOLD response patterns. • The differential BOLD response patterns highlight the possibility of fMRI biomarkers. Abbreviations: ANT: Anterior nucleus of thalamus; BOLD: Blood oxygen level-dependent; DBS: deep brain stimulation. Anterior nucleus of thalamus (ANT) deep brain stimulation (DBS) has shown promise as a treatment for medically refractory epilepsy. To better understand the mechanism of this intervention, we used functional magnetic resonance imaging (fMRI) to map the acute blood oxygen level-dependent (BOLD) response pattern to thalamic DBS in fully implanted patients with epilepsy. Two patients with epilepsy implanted with bilateral ANT-DBS devices underwent four fMRI acquisitions each, during which active left-sided monopolar stimulation was delivered in a 30-s DBS-ON/OFF cycling paradigm. Each fMRI acquisition featured left-sided stimulation of a different electrode contact to vary the locus of stimulation within the thalamus and to map the brain regions modulated as a function of different contact selection. To determine the extent of peri-electrode stimulation and the engagement of local structures during each fMRI acquisition, volume of tissue activated (VTA) modeling was also performed. Marked changes in the pattern of BOLD response were produced with thalamic stimulation, which varied with the locus of the active contact in each patient. BOLD response patterns to stimulation that directly engaged at least 5% of the anterior nuclear group by volume were characterized by changes in the bilateral putamen, thalamus, and posterior cingulate cortex, ipsilateral middle cingulate cortex and precuneus, and contralateral medial prefrontal and anterior cingulate. The differential BOLD response patterns associated with varying thalamic DBS parameters provide mechanistic insights and highlight the possibilities of fMRI biomarkers of optimizing stimulation in patients with epilepsy. [ABSTRACT FROM AUTHOR]

Published

2021